/*********************************************************************** * * * This software is part of the ast package * * Copyright (c) 1985-2008 AT&T Intellectual Property * * and is licensed under the * * Common Public License, Version 1.0 * * by AT&T Intellectual Property * * * * A copy of the License is available at * * http://www.opensource.org/licenses/cpl1.0.txt * * (with md5 checksum 059e8cd6165cb4c31e351f2b69388fd9) * * * * Information and Software Systems Research * * AT&T Research * * Florham Park NJ * * * * Glenn Fowler * * David Korn * * Phong Vo * * * ***********************************************************************/ #include "sfhdr.h" static char* Version = "\n@(#)$Id: sfio (AT&T Research) 2008-07-17 $\0\n"; /* Functions to set a given stream to some desired mode ** ** Written by Kiem-Phong Vo. ** ** Modifications: ** 06/27/1990 (first version) ** 01/06/1991 ** 07/08/1991 ** 06/18/1992 ** 02/02/1993 ** 05/25/1993 ** 02/07/1994 ** 05/21/1996 ** 08/01/1997 ** 08/01/1998 (extended formatting) ** 09/09/1999 (thread-safe) ** 02/01/2001 (adaptive buffering) ** 05/31/2002 (multi-byte handling in sfvprintf/vscanf) ** 09/06/2002 (SF_IOINTR flag) ** 11/15/2002 (%#c for sfvprintf) ** 05/31/2003 (sfsetbuf(f,f,align_size) to set alignment for data) ** (%I1d is fixed to handle "signed char" correctly) ** 01/01/2004 Porting issues to various platforms resolved. ** 06/01/2008 Allowing notify() at entering/exiting thread-safe routines. */ /* the below is for protecting the application from SIGPIPE */ #if _PACKAGE_ast #include #include #define Sfsignal_f Sig_handler_t #else #include typedef void(* Sfsignal_f)_ARG_((int)); #endif static int _Sfsigp = 0; /* # of streams needing SIGPIPE protection */ /* done at exiting time */ #if __STD_C static void _sfcleanup(void) #else static void _sfcleanup() #endif { reg Sfpool_t* p; reg Sfio_t* f; reg int n; reg int pool; f = (Sfio_t*)Version; /* shut compiler warning */ /* set this so that no more buffering is allowed for write streams */ _Sfexiting = 1001; sfsync(NIL(Sfio_t*)); for(p = &_Sfpool; p; p = p->next) { for(n = 0; n < p->n_sf; ++n) { if(!(f = p->sf[n]) || SFFROZEN(f) ) continue; SFLOCK(f,0); SFMTXLOCK(f); /* let application know that we are leaving */ (void)SFRAISE(f, SF_ATEXIT, NIL(Void_t*)); if(f->flags&SF_STRING) continue; /* from now on, write streams are unbuffered */ pool = f->mode&SF_POOL; f->mode &= ~SF_POOL; if((f->flags&SF_WRITE) && !(f->mode&SF_WRITE)) (void)_sfmode(f,SF_WRITE,1); if(((f->bits&SF_MMAP) && f->data) || ((f->mode&SF_WRITE) && f->next == f->data) ) (void)SFSETBUF(f,NIL(Void_t*),0); f->mode |= pool; SFMTXUNLOCK(f); SFOPEN(f,0); } } } /* put into discrete pool */ #if __STD_C int _sfsetpool(Sfio_t* f) #else int _sfsetpool(f) Sfio_t* f; #endif { reg Sfpool_t* p; reg Sfio_t** array; reg int n, rv; if(!_Sfcleanup) { _Sfcleanup = _sfcleanup; (void)atexit(_sfcleanup); } if(!(p = f->pool) ) p = f->pool = &_Sfpool; POOLMTXENTER(p); rv = -1; if(p->n_sf >= p->s_sf) { if(p->s_sf == 0) /* initialize pool array */ { p->s_sf = sizeof(p->array)/sizeof(p->array[0]); p->sf = p->array; } else /* allocate a larger array */ { n = (p->sf != p->array ? p->s_sf : (p->s_sf/4 + 1)*4) + 4; if(!(array = (Sfio_t**)malloc(n*sizeof(Sfio_t*))) ) goto done; /* move old array to new one */ memcpy((Void_t*)array,(Void_t*)p->sf,p->n_sf*sizeof(Sfio_t*)); if(p->sf != p->array) free((Void_t*)p->sf); p->sf = array; p->s_sf = n; } } /* always add at end of array because if this was done during some sort of walk thru all streams, we'll want the new stream to be seen. */ p->sf[p->n_sf++] = f; rv = 0; done: POOLMTXRETURN(p, rv); } /* create an auxiliary buffer for sfgetr/sfreserve/sfputr */ #if __STD_C Sfrsrv_t* _sfrsrv(reg Sfio_t* f, reg ssize_t size) #else Sfrsrv_t* _sfrsrv(f,size) reg Sfio_t* f; reg ssize_t size; #endif { Sfrsrv_t *rsrv, *rs; /* make buffer if nothing yet */ size = ((size + SF_GRAIN-1)/SF_GRAIN)*SF_GRAIN; if(!(rsrv = f->rsrv) || size > rsrv->size) { if(!(rs = (Sfrsrv_t*)malloc(size+sizeof(Sfrsrv_t)))) size = -1; else { if(rsrv) { if(rsrv->slen > 0) memcpy(rs,rsrv,sizeof(Sfrsrv_t)+rsrv->slen); free(rsrv); } f->rsrv = rsrv = rs; rsrv->size = size; rsrv->slen = 0; } } if(rsrv && size > 0) rsrv->slen = 0; return size >= 0 ? rsrv : NIL(Sfrsrv_t*); } #ifdef SIGPIPE #if __STD_C static void ignoresig(int sig) #else static void ignoresig(sig) int sig; #endif { signal(sig, ignoresig); } #endif #if __STD_C int _sfpopen(reg Sfio_t* f, int fd, int pid, int stdio) #else int _sfpopen(f, fd, pid, stdio) reg Sfio_t* f; int fd; int pid; int stdio; /* stdio popen() does not reset SIGPIPE handler */ #endif { reg Sfproc_t* p; if(f->proc) return 0; if(!(p = f->proc = (Sfproc_t*)malloc(sizeof(Sfproc_t))) ) return -1; p->pid = pid; p->size = p->ndata = 0; p->rdata = NIL(uchar*); p->file = fd; p->sigp = (!stdio && pid >= 0 && (f->flags&SF_WRITE)) ? 1 : 0; #ifdef SIGPIPE /* protect from broken pipe signal */ if(p->sigp) { Sfsignal_f handler; (void)vtmtxlock(_Sfmutex); if((handler = signal(SIGPIPE, ignoresig)) != SIG_DFL && handler != ignoresig) signal(SIGPIPE, handler); /* honor user handler */ _Sfsigp += 1; (void)vtmtxunlock(_Sfmutex); } #endif return 0; } #if __STD_C int _sfpclose(reg Sfio_t* f) #else int _sfpclose(f) reg Sfio_t* f; /* stream to close */ #endif { Sfproc_t* p; int pid, status; if(!(p = f->proc)) return -1; f->proc = NIL(Sfproc_t*); if(p->rdata) free(p->rdata); if(p->pid < 0) status = 0; else { /* close the associated stream */ if(p->file >= 0) CLOSE(p->file); /* wait for process termination */ #if _PACKAGE_ast sigcritical(SIG_REG_EXEC|SIG_REG_PROC); #endif while ((pid = waitpid(p->pid,&status,0)) == -1 && errno == EINTR) ; if(pid == -1) status = -1; #if _PACKAGE_ast sigcritical(0); #endif #ifdef SIGPIPE (void)vtmtxlock(_Sfmutex); if(p->sigp && (_Sfsigp -= 1) <= 0) { Sfsignal_f handler; if((handler = signal(SIGPIPE,SIG_DFL)) != SIG_DFL && handler != ignoresig) signal(SIGPIPE,handler); /* honor user handler */ _Sfsigp = 0; } (void)vtmtxunlock(_Sfmutex); #endif } free(p); return status; } #if __STD_C static int _sfpmode(Sfio_t* f, int type) #else static int _sfpmode(f,type) Sfio_t* f; int type; #endif { Sfproc_t* p; if(!(p = f->proc) ) return -1; if(type == SF_WRITE) { /* save unread data */ p->ndata = f->endb-f->next; if(p->ndata > p->size) { if(p->rdata) free((char*)p->rdata); if((p->rdata = (uchar*)malloc(p->ndata)) ) p->size = p->ndata; else { p->size = 0; return -1; } } if(p->ndata > 0) memcpy((Void_t*)p->rdata,(Void_t*)f->next,p->ndata); f->endb = f->data; } else { /* restore read data */ if(p->ndata > f->size) /* may lose data!!! */ p->ndata = f->size; if(p->ndata > 0) { memcpy((Void_t*)f->data,(Void_t*)p->rdata,p->ndata); f->endb = f->data+p->ndata; p->ndata = 0; } } /* switch file descriptor */ if(p->pid >= 0) { type = f->file; f->file = p->file; p->file = type; } return 0; } #if __STD_C int _sfmode(reg Sfio_t* f, reg int wanted, reg int local) #else int _sfmode(f, wanted, local) reg Sfio_t* f; /* change r/w mode and sync file pointer for this stream */ reg int wanted; /* desired mode */ reg int local; /* a local call */ #endif { reg int n; Sfoff_t addr; reg int rv = 0; SFONCE(); /* initialize mutexes */ if(wanted&SF_SYNCED) /* for (SF_SYNCED|SF_READ) stream, just junk data */ { wanted &= ~SF_SYNCED; if((f->mode&(SF_SYNCED|SF_READ)) == (SF_SYNCED|SF_READ) ) { f->next = f->endb = f->endr = f->data; f->mode &= ~SF_SYNCED; } } if((!local && SFFROZEN(f)) || (!(f->flags&SF_STRING) && f->file < 0)) { if(local || !f->disc || !f->disc->exceptf) { local = 1; goto err_notify; } for(;;) { if((rv = (*f->disc->exceptf)(f,SF_LOCKED,0,f->disc)) < 0) return rv; if((!local && SFFROZEN(f)) || (!(f->flags&SF_STRING) && f->file < 0) ) { if(rv == 0) { local = 1; goto err_notify; } else continue; } else break; } } if(f->mode&SF_GETR) { f->mode &= ~SF_GETR; #ifdef MAP_TYPE if((f->bits&SF_MMAP) && (f->tiny[0] += 1) >= (4*SF_NMAP) ) { /* turn off mmap to avoid page faulting */ sfsetbuf(f,(Void_t*)f->tiny,(size_t)SF_UNBOUND); f->tiny[0] = 0; } else #endif if(f->getr) { f->next[-1] = f->getr; f->getr = 0; } } if(f->mode&SF_STDIO) /* synchronizing with stdio pointers */ (*_Sfstdsync)(f); if(f->disc == _Sfudisc && wanted == SF_WRITE && sfclose((*_Sfstack)(f,NIL(Sfio_t*))) < 0 ) { local = 1; goto err_notify; } if(f->mode&SF_POOL) { /* move to head of pool */ if(f == f->pool->sf[0] || (*_Sfpmove)(f,0) < 0 ) { local = 1; goto err_notify; } f->mode &= ~SF_POOL; } SFLOCK(f,local); /* buffer initialization */ wanted &= SF_RDWR; if(f->mode&SF_INIT) { if(!f->pool && _sfsetpool(f) < 0) { rv = -1; goto done; } if(wanted == 0) goto done; if(wanted != (int)(f->mode&SF_RDWR) && !(f->flags&wanted) ) goto err_notify; if((f->flags&SF_STRING) && f->size >= 0 && f->data) { f->mode &= ~SF_INIT; f->extent = ((f->flags&SF_READ) || (f->bits&SF_BOTH)) ? f->size : 0; f->here = 0; f->endb = f->data + f->size; f->next = f->endr = f->endw = f->data; if(f->mode&SF_READ) f->endr = f->endb; else f->endw = f->endb; } else { n = f->flags; (void)SFSETBUF(f,f->data,f->size); f->flags |= (n&SF_MALLOC); } } if(wanted == (int)SFMODE(f,1)) goto done; switch(SFMODE(f,1)) { case SF_WRITE: /* switching to SF_READ */ if(wanted == 0 || wanted == SF_WRITE) break; if(!(f->flags&SF_READ) ) goto err_notify; else if(f->flags&SF_STRING) { SFSTRSIZE(f); f->endb = f->data+f->extent; f->mode = SF_READ; break; } /* reset buffer */ if(f->next > f->data && SFFLSBUF(f,-1) < 0) goto err_notify; if(f->size == 0) { /* unbuffered */ f->data = f->tiny; f->size = sizeof(f->tiny); } f->next = f->endr = f->endw = f->endb = f->data; f->mode = SF_READ|SF_LOCK; /* restore saved read data for coprocess */ if(f->proc && _sfpmode(f,wanted) < 0) goto err_notify; break; case (SF_READ|SF_SYNCED): /* a previously sync-ed read stream */ if(wanted != SF_WRITE) { /* just reset the pointers */ f->mode = SF_READ|SF_LOCK; /* see if must go with new physical location */ if((f->flags&(SF_SHARE|SF_PUBLIC)) == (SF_SHARE|SF_PUBLIC) && (addr = SFSK(f,0,SEEK_CUR,f->disc)) != f->here) { #ifdef MAP_TYPE if((f->bits&SF_MMAP) && f->data) { SFMUNMAP(f,f->data,f->endb-f->data); f->data = NIL(uchar*); } #endif f->endb = f->endr = f->endw = f->next = f->data; f->here = addr; } else { addr = f->here + (f->endb - f->next); if(SFSK(f,addr,SEEK_SET,f->disc) < 0) goto err_notify; f->here = addr; } break; } /* fall thru */ case SF_READ: /* switching to SF_WRITE */ if(wanted != SF_WRITE) break; else if(!(f->flags&SF_WRITE)) goto err_notify; else if(f->flags&SF_STRING) { f->endb = f->data+f->size; f->mode = SF_WRITE|SF_LOCK; break; } /* save unread data before switching mode */ if(f->proc && _sfpmode(f,wanted) < 0) goto err_notify; /* reset buffer and seek pointer */ if(!(f->mode&SF_SYNCED) ) { n = f->endb - f->next; if(f->extent >= 0 && (n > 0 || (f->data && (f->bits&SF_MMAP))) ) { /* reset file pointer */ addr = f->here - n; if(SFSK(f,addr,SEEK_SET,f->disc) < 0) goto err_notify; f->here = addr; } } f->mode = SF_WRITE|SF_LOCK; #ifdef MAP_TYPE if(f->bits&SF_MMAP) { if(f->data) SFMUNMAP(f,f->data,f->endb-f->data); (void)SFSETBUF(f,(Void_t*)f->tiny,(size_t)SF_UNBOUND); } #endif if(f->data == f->tiny) { f->endb = f->data = f->next = NIL(uchar*); f->size = 0; } else f->endb = (f->next = f->data) + f->size; break; default: /* unknown case */ err_notify: if((wanted &= SF_RDWR) == 0 && (wanted = f->flags&SF_RDWR) == SF_RDWR) wanted = SF_READ; /* set errno for operations that access wrong stream type */ if(wanted != (f->mode&SF_RDWR) && f->file >= 0) errno = EBADF; if(_Sfnotify) /* notify application of the error */ (*_Sfnotify)(f, wanted, (void*)((long)f->file)); rv = -1; break; } done: SFOPEN(f,local); return rv; }